Active matrix display device

ABSTRACT

A wiring formed on a substrate is oxidized and the oxide is used as a mask for forming source and drain impurity regions of a transistor, or as a material for insulating wirings from each other, or as a dielectric of a capacitor. The thickness of the oxide is determined depending on the purpose of the oxide. In a transistor adapted to be used in an active-matrix liquid-crystal display, the channel length, the distance between the source region and the drain region, is made larger than the length of the gate electrode taken in the longitudinal direction of the channel. Offset regions are formed in the channel region on the sides of the source and drain regions. No or very weak electric fields are applied to these offset regions from the gate electrode.

This application is a Divisional of application Ser. No. 08/455,156,filed May 31, 1995, now U.S. Pat. No. 5,849,611, which is a Divisionalof application Ser. No. 08/014,455, filed Feb. 3, 1993, now U.S. Pat.No. 5,485,019.

FIELD OF THE INVENTION

The present invention relates to a semiconductor device, semiconductorintegrated circuit such as an insulating gate field-effect translatorand a manufacturing method thereof.

Particularly, the present invention relates to an active-matrixelectro-optical device and, more particularly, to a field-effecttransistor which can be applied to an active-matrix liquid-crystalelectro-optical device or the like and has definite switchingcharacteristics. Also, the invention relates to a method of fabricatingsuch a field-effect transistor.

BACKGROUND OF THE INVENTION

The prior art thin-film insulated-gate field-effect transistor used inan active-matrix liquid-crystal electro-optical device is constructed asshown in FIG. 2. A blocking layer 208 is formed on an insulatingsubstrate 209. A semiconductor layer having a source 204, a drain 205,and a channel region 203 is formed on the blocking layer 208. Agate-insulating film 202 and a gate electrode 201 are laminated on thesemiconductor layer. An interlayer insulating film 211 is formed on thegate-insulating film 202 and on the gate electrode 201. A sourceelectrode 206 and a drain electrode 207 are formed on the interlayerinsulating film 211 and on the semiconductor layer.

This prior art insulated-gate FET is manufactured in the sequencedescribed now. First, the blocking layer 208 is formed on the glasssubstrate 209 by sputtering while using SiO₂ as a target. Then, thesemiconductor layer is formed by plasma-assisted CVD and patterned toform the semiconductor layer which will have the source, drain, andchannel region. Then, silicon oxide is sputtered to form thegate-insulating film 202. Subsequently, an electrically conductive layerwhich is heavily doped with phosphorus and used to form the gateelectrode is formed by low-pressure CVD. The conductive layer is thanpatterned to form the gate electrode 201. Thereafter, dopant ions areimplanted while using the gate electrode as a mask, so that the source205 and the drain 204 are fabricated. Then, the laminate is thermallytreated to activate it.

In the insulated-gate FET fabricated in this way, the length of the gateelectrode 201 taken in the longitudinal direction of the channel issubstantially identical with the channel length, indicated by 210. Inthe case of the n-channel structure, the current-voltage characteristicof the FET of this structure is shown in FIG. 3. This FET has thedisadvantage that in the reverse bias region 250, the leakage currentincreases with increasing the voltage applied between the source anddrain. Where this device is used in an active-matrix liquid-crystalelectro-optical device, if the leakage current increases in this way,the electric charge stored in a liquid crystal 302 by a writing current300 is discharged as a leakage current 301 through the leaking portionof the device during the non-writing period, as shown in FIG. 5(A). Inthis manner, it has been impossible to obtain good contrast.

A conventional method of solving this problem is to add a capacitor 303for holding electric charge, as shown in FIG. 5(B). However, in order toform such capacitors, capacitive electrodes made of metal interconnectsare needed. This results in a decrease in the aperture ratio. Also, itis reported that the aperture ratio is improved by fabricating thecapacitors from transparent electrodes of ITO. Nonetheless, this schemenecessitates an excess process and hence has not enjoyed popularity.

Where only one of the source and drain of this insulated-gate FET isconnected with a capacitive device or a capacitor and this transistor isused as a switching device, e.g., in the case of a well-known dynamicrandom access memory (DRAM) of the 1 transistor/cell type or in the caseof an active liquid crystal display having pixels each of which has thecircuit shown in FIG. 5(A) or 5(B), it is known that the voltage at thecapacitor device is varied by the existence of a parasitic capacitancebetween the gate electrode and the drain or source.

The variation ΔV in this voltage is in proportion to the gate voltageV_(G) and to the parasitic capacitance and is in inverse proportion tothe sum of the capacitance of the capacitive device and the parasiticcapacitance. Therefore, it is customary to fabricate the transistor bythe self-aligning technology to reduce the parasitic capacitance, thussuppressing variations in the voltage. However, as the dimensions ofdevices decrease, the contribution of the parasitic capacitance becomesso large that it can no longer be neglected even if the self-aligningprocess is exploited.

In an attempt to reduce the variation ΔV, a new method has beenproposed. In particular, as shown in FIG. 5(B), a capacitor other thanthe proper capacitive device is connected in parallel to increase theapparent capacitance of the capacitive device. As described previously,however, the increase in the area of the capacitor cannot be neglectedfor DRAMs. The decrease in the numerical aperture cannot be neglectedfor liquid-crystal displays.

Conventionally, a conductive material in single-layers or multilayerswas utilized as a wiring material or an electrode material of asemiconductor device (semiconductor element) of an insulating gatefield-effect transistor and a semiconductor integrated circuit utilizinga number of them. By overlaying such wirings with insulating filmsbetween them, it was comparatively easy to form the wirings.

In the conventional method, it was a problem that short circuit betweenan upper wiring and a lower wiring happened many times becauseinsulation between wirings was made by an insulating film of 1 μmthickness at most (In many cases, it was a single-layer.). This shortcircuit was mainly caused by bubbles, holes (pin holes), dusts and thelike made in the insulating film. Conventionally, in a semiconductorintegrated circuit formed especially on a silicon single-crystalsubstrate, an insulating film was formed of a material likephosphosilicate glass, and was half melted at a high-temperature ofapproximately 1000° C. Thus insulating property between wirings wasimproved by making the bubbles or pin holes disappeared. This processcan also make smoother the unevenness generated on the substrate by eachprocess of forming a thin film. It was prominently effective especiallyto prevent disconnection of metal wires formed on the insulating film.

However, this method is not applicable to every kind of semiconductordevices and integrated circuits. It is quite natural that this method isnot applicable to semiconductor devices and integrated circuitsutilizing a material which is not proof against such a high temperature.For example, this method is not applicable to a cheap glass substrate ofwhich distortion point is usually 750° C. or less. A material likealuminum to decrease resistance as a wiring could not be utilized,either.

Generally, a higher process temperature needed better heat resistancefor the device in the process. This made equipment investment huge. Thebigger an object like a substrate to be treated became, the more theamount of investment became exponentially. For example, when a thin filmtransistor (TFT) is produced to use it as a big liquid crystal display,the size of the substrate should be 300 mm×300 mm or bigger, and it wasactually impossible to adopt a high temperature process as high as 1000°C.

The present invention was made to solve above problems, and is aimed atobtaining bigger effects by a totally creative method which has neverbeen thought of before.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide an insulated-gateFET free of the foregoing problems.

The above object is achieved by an insulated-gate FET in which thechannel length, i.e., the distance between the source region and thedrain region, is made larger than the length of the gate electrode takenin the longitudinal direction of the channel (the direction of thechannel length), whereby offset regions are formed in those portions ofthe channel regions which are in contact with the source and drainregions, respectively. The offset regions undergo no or very weakelectric field from the gate electrode. The current-voltagecharacteristic of this device is shown in FIG. 4.

It is another object of the invention to provide a method for formingthe insulated-gate FET described in the preceding paragraph.

Other objects and features of the invention will appear in the course ofthe description which follows.

Referring to FIG. 1, the fundamental structure of a field-effecttransistor according to the invention is shown. This transistor has aninsulating substrate 105 and a blocking layer 104 formed on thesubstrate 105. A semiconductor layer which becomes a source region 100,a drain region 101, and a channel region 109 is formed on the blockinglayer 104. A gate-insulating film 110 is formed on the channel region109. A gate electrode 111 is formed on the gate-insulating film 110. Anoxide layer 112 which is an insulating layer is formed on the gateelectrode 111. The oxide layer 112 is formed by anodizing a materialwhich can be anodized. A source electrode 102 and a drain electrode 103are formed so as to be in contact with the source region and the drainregion, respectively. No interlayer insulator is shown in FIG. 1, butwhere the parasitic capacitance between the gate electrode or theinterconnects to this gate and the source, the drain, or theinterconnects to the source or drain poses a problem, an interlayerinsulator may be formed in the same way as in the prior art techniques.Examples of this will be described later.

Referring still to FIG. 1, the gate electrode portion which becomes thegate electrode 111 and the oxide layer 112 is made of a material thatcan be anodized. The surface portion of the gate electrode portion isanodized to form the oxide layer 112. The distance between the sourceregion 100 and the drain region 101 which are to be implanted with ions,i.e., the channel length 108, is larger than the substantial length ofthe gate electrode 111 taken in the longitudinal direction of thechannel by a length which is about twice as large as the thickness ofthe oxide layer 112. The gate electrode portion comprises metal orsemiconductor. Chiefly, the material of the gate electrode portion isone selected from titanium (Ti), aluminum (Al), tantalum (Ta), chromium(Cr), and silicon (Si). Alternatively, the gate electrode portion ismade of an alloy of some of these materials.

As a result, those portions 106 and 107 of the channel region 109 whichare on the opposite sides of the gate-insulating film 110 from theportions of the oxide layer 112 formed on both sides of the gateelectrode receive no electric field from the gate electrode orexperience much weaker field than the portions immediately under thegate electrode. These regions 106 and 107 are hereinafter, especiallywhere they are comparable to the channel region in crystallinity anddose, referred to as the offset regions.

These regions 106 and 107 can be made of doped amorphous materials. Morestrictly, it is only necessary that the regions 106 and 107 be inferiorin crystallinity to the adjacent source region 100 and drain region 101.For example, if the source region 100 and the drain region 101 consistof polysilicon having large crystal grains, then it is only necessarythat the regions 106 and 107 be made of amorphous silicon orsemi-amorphous silicon that is slightly superior in crystallinity toamorphous silicon. If the regions 100 and 101 are made of semi-amorphoussilicon, the regions 106 and 107 can be made of amorphous silicon. Ofcourse, these amorphous materials are required to be sufficientlytreated so that they behave as semiconductors. As an example, in orderto minimize dangling bonds, it is necessary that these bonds besufficiently terminated by hydrogen or a halogen element.

A good TFT (thin-film transistor) characteristic as shown in FIG. 9(a)could be obtained by forming these amorphous regions. FIG. 9(b) showsthe current-voltage characteristic of a thin-film transistor of theprior art insulated-gate transistor structure. As can be seen bycomparing these characteristic curves, very large leakage current wasobserved in the reverse direction when the prior art method was used. Inaccordance with the present invention, substantially amorphous regionsare formed, thus improving the characteristic. That is, formation ofdoped amorphous regions yields the same advantages as the formation ofthe previously described offset regions.

Why the formation of the amorphous regions improves the characteristicis not fully understood. One possible cause is as follows. In theamorphous regions, the added dopant element is ionized at a lower ratethan in the crystal regions. Therefore, if dopants are added at the samedose, the amorphous regions behave as though they had lower dopantconcentrations. That is, regions substantially similar to lightly dopeddrains are formed. For instance, the ionization rate of silicon inamorphous state is 0.1-10% at room temperature, which is much lower thanthe ionization rate of almost 100% of single-crystal or polycrystalsemiconductors.

Another possible cause is that the bandgap in amorphous state is largerthan the bandgap in crystalline state. For example, this can beexplained away by the energy band diagrams of FIGS. 9, (e) and (f). Intransistors of normal, lightly doped drain structure, the energy bandsbetween the source, channel, and drain are shown in FIGS. 9, (c) and(d). The central raised portion indicates the channel region. Thestaircase portions indicate lightly doped drain regions. FIG. 9(c)indicates the case in which no voltage is applied to the gate electrode.When a large negative voltage is applied to the gate electrode, thecondition shown in FIG. 9(d) appears. At this time, forbidden bandsexist between the source and the channel region and between the channelregion and the drain to thereby inhibit movement of carries such aselectrons and holes. However, the carriers pass across the gap by thetunnel effect or by hopping the trap level within the bandgap. In normalthin-film transistors (TFTs) which are not of the lightly doped drainstructure, the gap width is smaller and so electric current flows moreeasily. This is considered to be the leakage in the reverse direction.This phenomenon is especially conspicuous for TFTs and possibly causedby numerous trap levels due to grain boundaries because TFTs are made ofinhomogeneous materials such as polycrystals.

Where the bandgap in the lightly doped drain region is increased, theabove-described leakage in the reverse direction decreases. This exampleis shown in FIGS. 9, (e) and (f). FIG. 9(e) shows the condition in whichno voltage is applied to the gate. FIG. 9(f) shows the condition inwhich a large negative voltage is applied to the gate. When a negativevoltage is applied as shown in FIG. 9(f), the width of the gap betweenthe source and channel region and the width of the gap between thechannel region and the drain are larger than those in case of FIG. 9(d),as can be seen by comparing FIG. 9(f) with FIG. 9(d). The tunnel effectis affected greatly by the width of the tunnel carrier (in this case thewidth of the gap). The probability that carriers tunnel through the gapis reduced greatly with increasing the width of the gap slightly. Also,hopping via local energy levels is a composite tunnel effect and,therefore, if the width of the gap increases, the probability dropsdrastically. For these reasons, formation of lightly doped drain regionshaving large bandgaps is considered as advantageous. The bandgaps ofamorphous silicon is 1.5 to 1.8 eV, while the bandgap of polycrystallinesilicon is 1.1 eV. If materials having such wide bandgaps are used inlightly doped drains, a quite ideal situation occurs.

To fabricate a semiconductor device in accordance with the presentinvention, especially a semiconductor device having the aforementionedoffset regions, the gate electrode portion is formed out of a materialcapable of being anodized after the semiconductor layer becoming thesource, drain, and the channel region and the gate-insulating layer 110are formed. Subsequently, dopant ions which impart p- or n-type to thesemiconductor layer are implanted into this semiconductor layer to formthe source region 100 and the drain region 101. Thereafter, the surfaceof the gate electrode portion is anodized (anodic oxidized) to form thegate electrode 111 and the oxide layer 112. Thereafter, a thermaltreatment or other step is carried out.

Alternatively, after forming the semiconductor layer and thegate-insulating layer 110, the gate electrode portion is fabricated outof a material that can be anodized, followed by anodization (anodicoxidation) of the surface of the gate electrode portion to form the gateelectrode 111 and the oxide layer 112. Then, dopant ions are implantedinto the semiconductor layer to impart p- or n-type to it, forming thesource region 100 and the drain region 101. Thereafter, a thermaltreatment is effected.

By carrying out these steps, insulated-gate FETs in which the channellength is greater than the length of the gate electrode taken in thelongitudinal direction of the channel can be easily and certainlyfabricated without producing variations in the performance which wouldotherwise be caused by mask misalignment.

Another method of fabricating the novel semiconductor device havingamorphous regions is initiated by forming the semiconductor layerbecoming the source, drain, and channel region and the gate-insulatinglayer 110. Then, the gate electrode portion is fabricated from amaterial that can be anodized. Subsequently, dopant ions are implantedso that the semiconductor layer is doped p- or n-type. As a result, thesemiconductor layer is made amorphous. The source region 100, the drainregion 101, and their adjacent amorphous regions 106 and 107 are formed.Thereafter, the surface portion of the gate electrode portion isanodized to form the gate electrode 111 and the oxide layer 112. At thistime, the surface of the gate electrode is made to retreat by theoxidation. Then, only the source region 100 and the drain region 101 maybe recrystallized while using the gate electrode portion as a mask by aself-aligning process employing laser annealing or flash lamp annealingtechniques. This process is of the self-aligning type, because the gateelectrode portion shades the underlying doped regions located under thegate electrode portion, thus inhibiting recrystallization of these dopedregions.

Where an ion implantation process is utilized, the spreading of thedoped regions due to secondary diffusion of ions can be calculated fromthe acceleration energy of the ions. Also, the retreat of the gateelectrode is determined by the thickness of the oxide layer and so theretreat is also taken as a design parameter. In accordance with thepresent invention, the positional relation between the gate electrodeand the doped regions can be optimized by accurate design. Inparticular, the thickness of the oxide layer can be controlled totolerances less than 10 nm. Also, the secondary scattering producedduring ion implantation can be controlled to tolerances of the sameorder. Consequently, the positional relation can be controlled totolerances less than 10 nm during the fabrication.

In this way, the invention requires no further accurate mask alignment.The possibility that the production yield is deteriorated by theinvention is low. Rather, the inventive device has greatly improvedcharacteristics.

The present invention is aimed at providing an insulating film formedaround at least one wiring and formed of the material for the wiring. Itis desirable to form such an insulating film by oxidizing the materialso as not to make bubbles or pin holes. Anodic oxidation, plasmaoxidation method, or thermal oxidation method is desirable as a methodof oxidation. As an appropriate material of the wiring, simplesubstances, semiconductors, or alloys of silicon, aluminum, tantalum,titanium, tungsten, or molybdenum, and what is more, a metal compound ina condition of not being oxidized, such as tantalum nitride, titaniumnitride, tungsten silicide, and molybdenum silicide is appropriate. Forexample, a nitride like tantalum nitride changes to be tantalum oxide byanodic oxidation.

A semiconductor device in accordance with the present inventioncomprises:

a substrate;

a gate electrode of a transistor provided on said substrate;

a first wiring provided on said substrate in the same layer as said gateelectrode; and

a second wiring provided in a layer different from said same layer,

wherein said first wiring and said second wiring cross each other, andsaid first wiring is provided with an oxide of a material of said firstwiring on an upper or side surface of said first wiring, and said gateelectrode is provided with an oxide of a material of said gate electrodeon an upper or side surface of said gate electrode at a thicknessdifferent from that of said oxide of the material of said first wiringat the crossing.

The semiconductor device further comprises source and drain regions onthe substrate, a channel region provided on the substrate between thesource and drain regions, and a gate insulating layer provided betweenthe channel region and the gate electrode.

The first wiring comprises, for example, silicon, aluminum, tantalum,titanium, tungsten, molybdenum, an alloy thereof, tantalum nitride,titanium nitride, tungsten silicide, or molybdenum silicide.

It is natural capability of insulation is improved if an additionalinsulating film is formed by a method such as chemical vapor deposition(CVD), because above mentioned oxide has a good insulation. However,characteristic of the present invention is not to make the oxideinsulating film in a homogeneous thickness around the material of thewiring over the whole surface, but to determine thicknesses of the oxideinsulating film according to location thereof to accomplish the purpose.

The present invention is firstly related to an MIS(metal-insulator-semiconductor structure) transistor, and amanufacturing technology thereof with such wiring oxide as a mask. Inthe case of forming an impurity region (source, drain) of an MIStransistor by well known self-align method, a slight overlap wassometimes made between the gate electrode and the source region, drainregion, because impurities were introduced with a gate electrode as amask. In this case, an electric field was concentrated to a portionwhere the drain and the gate electrode were close to each other. Thatsometimes broke the gate insulating film near it.

This inventor found that by separating the gate electrode from at leastone of the source and drain regions to provide an offset region betweenthe gate electrode and at least one of the source and drain regions,such concentration of electric field could be prevented and the gateinsulating film could be prevented from being broken. For example, thegate electrode is 500 to 5000 Å distant from at least one of the sourceand drain regions. Indeed, it was difficult to obtain such a minuteoffset region with good reproducibility by using a conventional method.In addition to the gate electrode, this inventor decided to use an oxidearound the gate electrode as a mask when an impurity was introduced.Moreover, this inventor found that above mentioned purpose can beachieved by strictly controlling the thickness of this oxide to be thesize of offset.

The inventor also found that characteristic of the MIS transistorchanges according to the size of the offset made here. In general, ifoffset was big, dielectric strength of a transistor obtained was high,and leak current between the source and drain was small, but mobilitywas low. On the contrary, if offset was small, mobility was high, butdielectric strength was low.

For example, both a transistor with high dielectric strength and atransistor which can be driven fast were sometimes needed in the samesubstrate, but they were not made separately in such case. The presentinvention is firstly characterized in that such transistors withdifferent characteristics are controlled by the size of offset (that is,thickness of oxide of wiring-gate electrode), and transistorsappropriate for different purposes are formed in the same substrate.

For example, in a liquid crystal display of TFT active matrix type, atransistor with big offset is formed as TFTs for active matrix, and onthe other hand, a transistor with small offset is formed as TFTs forperipheral circuits which must be driven fast, both of the transistorsbeing formed on the same substrate. In addition, a structure comprisinga logic circuit made of a transistor with small offset and an outputtransistor made of a transistor with big offset can be utilized for aperipheral circuit.

The present invention is secondly related to an MIS type transistor anda wiring connected to it. In a wiring in the same layer of the gateelectrode of the MIS type transistor, oxide is made thick in the portionwhere this wiring is crossed with an upper wiring. On the other hand, anoxide film of the wiring of the gate electrode is thinned or is notformed at all. In this case, the transistor can be driven at a highspeed because of small offset. On the other hand, at the portion wherethe wirings are crossed, an effect of good insulating property isobtained because of the thick oxide.

The present invention is thirdly related to a capacitor provided in asemiconductor circuit and to an integrated circuit with such acapacitor. They have a part of wirings as an electrode of a capacitor ofwhich peripheral portion is covered with its oxide. On the other hand,in other portions of the wirings, peripheral portions of wirings arecovered with an oxide at places where the wirings are crossed with upperwirings, too. By thinning oxide comprising a capacitor electrode,capacitance of the capacitor is made big. By thickening oxide at a placewhere wirings are crossed, and, by depositing additional oxide film onthe place, insulating property between the wirings is improved andcapacity coupling between them is decreased.

A semiconductor device in accordance with the present inventioncomprises:

a substrate;

a capacitor provided on said substrate;

a first wiring provided on said substrate in the same layer as a firstelectrode of said capacitor; and

a second wiring provided on said substrate in the same layer as a secondelectrode of said capacitor,

wherein said first wiring and said second wiring cross each other at alocation B other than that of said capacitor, and said first wiring isprovided with an oxide of a material of said first wiring on an upper orside surface of said first wiring, and said first electrode is providedwith an oxide of a material of said first electrode on an upper surfaceof said first electrode at a thickness different from that of said oxideof the material of said first wiring at the location B.

The first wiring comprises, for example, silicon, aluminum, tantalum,titanium, tungsten, molybdenum, an alloy thereof, tantalum nitride,titanium nitride, tungsten silicide, or molybdenum silicide. The oxideof the material of the first wiring is thicker than the oxide of thematerial of the first electrode.

The present invention is fourthly related to a method of oxidizingwirings in forming such oxide. There are three methods. The first methodis briefly shown in FIG. 19. As is shown in FIG. 19(A), a wiring 52 isformed directly or, if necessary, after deposition of a surface oxidefilm 51, on a substrate 50. A mask material 53 is provided to a portionforming a contact with upper wirings. It is important that the maskmaterial has a function of blocking oxidizing effect, and is selectedaccording to methods of oxidation. For example, in a method of thermaloxidation at a high temperature of several hundred centigrade, heatresistance is needed to a mask material. In this case, a material likesilicon nitride which can be easily deposited and has good heatresistance and good resistance to oxidation is appropriate. If thewiring is oxidized at a lower temperature than above, more materials areuseful. For example, if the process is performed at 400° C. or less, anorganic material such as polyimide can be utilized. Polyimide can beformed with a very low cost, because it does not need a vacuum apparatusfor formation. Moreover, its mass productivity is good. Especiallyphotosensitive polyimide (photoneece) is easy to use because patterningcan be performed by a conventional photolithography method.

Oxidation of the wiring is performed in this condition with a first maskbeing provided selectively on the wiring, and a thin oxide film isformed around the wiring as is shown in FIG. 19(B). The wiringcomprises, for example, silicon, aluminum, tantalum, titanium, tungsten,molybdenum, an alloy thereof, tantalum nitride, titanium nitride,tungsten silicide, or molybdenum silicide. A second mask 55 is formed ona region containing at least a portion of the first mask, and oxidationof the wiring is performed in the same way. Thus a thick oxide 56 isformed as is shown in FIG. 19(C). In this way, an oxide with differentthicknesses is obtained, which is characteristic of the presentinvention.

By removing the first mask and the second mask, a contact hole 57 isformed as is shown in FIG. 19(D). What is noteworthy is that thethickness of the oxide changes in steps until it reaches the contacthole. As a result, difference of the level to the contact hole can bedecreased. FIGS. 19(E) and (F) show the case when an upper wiring 59 isconnected to the contact hole 57. The upper wiring is formed on at leasta portion of a region from which the first mask is removed by the stepshown in FIG. 19(D). If etching selection ratio between an interlayerinsulator 58 and wiring oxide 54, 56 is enough and the area of thecontact formation region is wide enough, more gradual steps areobtainable as is shown in FIG. 19(E). The interlayer insulator 58 is notnecessarily needed. Because the thickness of the oxide under the upperwiring 59 becomes smaller in steps in the direction of the contact hole,disconnection of the upper wiring is difficult to happen. This method iseffective in the case that etching cannot be performed substantially,because etching of an oxide of wirings is difficult, or because enoughselection ratio with another material cannot be obtained.

The second method is shown in FIG. 20. As is shown in FIG. 20(A), awiring 62 is formed directly, or if necessary, after deposition of asurface oxide film 61, on a substrate 60. The wiring comprises, forexample, silicon, aluminum, tantalum, titanium, tungsten, molybdenum, analloy thereof, tantalum nitride, titanium nitride, tungsten silicide, ormolybdenum silicide. A thin oxide 63 is formed by oxidizing the surfaceof it. As is shown in FIG. 20(B), a mask material 64 is formed in aportion forming a contact hole. Oxidation of the wiring 62 oxidized at asurface of the wiring is performed in this condition with a mask beingprovided selectively on the wiring, and though the portion covered withthe mask material remains a thin oxide 66, but a thick oxide film 65 isformed on other portions. In this way, an oxide with differentthicknesses which is characteristic of the present invention isobtained. Then, the mask is removed.

As is shown in FIG. 20(D), the region 66 covered with a thin oxide isetched, and a contact hole 67 is formed in said surface after theremoval of the mask in at least a portion of a region from which themask is removed by the removing step of FIG. 20(C). In this case, too,the thickness of the oxide changes in steps until it reaches the contacthole. As a result, difference of level to the contact hole can bedecreased. FIGS. 20(E) and (F) show the case when an upper wiring 69 isconnected to the contact hole 67. The upper wiring 69 is formed at leastin a portion of the contact hole. An interlayer insulator 68 is notnecessarily needed.

The third method is shown in FIG. 21. As is shown in FIG. 21(A), awiring 72 is formed directly, or if necessary, after deposition of asubstrate oxide film 71, on a substrate 70. The wiring comprises, forexample, silicon, aluminum, tantalum, titanium, tungsten, molybdenum, analloy thereof, tantalum nitride, titanium nitride, tungsten silicide, ormolybdenum silicide. A thick oxide 73 is formed by oxidizing the surfaceof it. As is shown in FIG. 21(B), a thick oxide is etched byphotolithography method, and a thin oxide 75 is provided. In this way,an oxide with different thicknesses which is characteristic of thepresent invention is obtained.

A contact hole 76 is formed further to a portion in which a thin oxideis formed, e.g. by selectively etching the wiring 72 oxidized at asurface of the wiring 72. In this case, too, the thickness of an oxidechanges in steps until it reaches the contact hole, and different levelto the contact hole can be decreased. An interlayer insulator is formedon the substrate after the etching for the formation of the contact hole76. A contact hole is formed in the interlayer insulator. FIG. 21(D) and(E) show the case when an upper wiring 78 is connected to the contacthole 76. The upper wiring 78 is formed over the contact hole. Theinterlayer insulator 77 is not necessarily needed. In this method, whenthe thick oxide 73 is etched to make it a thin oxide 75, if an etchingrate is not uniform, its thickness will not be homogeneous. Therefore,to make this method real, an etching technology of an oxide isimportant. On the other hand, in the first and second methods, thethickness of an oxide is decided by selective oxidation of wirings. Forexample, the thickness of an oxide is decided by temperature and time inthe case of thermal oxidation, and it is decided by voltage applied inthe case of anodic oxidation. As long as these parameters are fixed, thethickness of the oxide is equal. Therefore, these methods are moresecure method and have higher reliability compared with the thirdmethod.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-sectional view of a semiconductor device according tothe invention;

FIG. 2 is a cross-sectional view of a conventional semiconductor device;

FIG. 3 is a graph showing the current-voltage characteristic of theconventional semiconductor device shown in FIG. 2;

FIG. 4 is a graph showing the current-voltage characteristic of thenovel semiconductor device shown in FIG. 1;

FIGS. 5, (A) and (B), are circuit diagrams of portions of conventionalactive-matrix liquid-crystal electro-optical devices;

FIG. 6 is a circuit diagram of a portion of an active-matrixliquid-crystal electro-optical device according to the invention, thedevice forming Example 1 of the invention;

FIG. 7 is a plan view of the portion of the novel active-matrixliquid-crystal electro-optical device shown in FIG. 6;

FIGS. 8, (A)-(F), are cross-sectional views of a portion of the novelactive-matrix liquid-crystal electro-optical device shown in FIGS. 6 and7, illustrating the sequence in which the device is fabricated;

FIGS. 9, (a) and (b), are graphs showing characteristics of thin-filmtransistors;

FIGS. 9, (c)-(f), are diagrams illustrating the principle of operationof thin-film transistors according to the invention;

FIGS. 10, (A)-(D), are cross-sectional views of a thin-film transistoraccording to Example 5 of the invention, illustrating the sequence inwhich the device is fabricated;

FIGS. 11(A) to 11(C) are plan views showing a method for forming a TFTin accordance with the present invention;

FIGS. 12, (A)-(D), are cross-sectional views of a thin-film transistoraccording to Example 6 of the invention, illustrating the sequence inwhich the device is fabricated;

FIG. 13 is a plan view of an active-matrix liquid-crystalelectro-optical device according to Example 6 of the invention;

FIG. 14 is a circuit diagram of a portion of an active-matrixliquid-crystal electro-optical device according to Example 7;

FIGS. 15(A)-(E) shows a manufacturing method in accordance with thepresent invention;

FIGS. 16(A)-(E) shows a manufacturing method in accordance with thepresent invention;

FIGS. 17(A)-(E) shows a manufacturing method in accordance with thepresent invention;

FIGS. 18(A)-(C) shows applicable examples of the present invention;

FIGS. 19(A)-(F) shows a manufacturing process of forming a contact inaccordance with the present invention;

FIGS. 20(A)-(F) shows a manufacturing process of forming a contact inaccordance with the present invention;

FIGS. 21(A)-(E) shows a manufacturing process of forming a contact inaccordance with the present invention;

FIGS. 22(A)-(E) shows a manufacturing method in accordance with thepresent invention; and

FIGS. 23(A)-(E) shows a manufacturing method in accordance with thepresent invention.

DETAILED DESCRIPTION OF THE INVENTION EXAMPLE 1

A viewfinder for a video camera, using a liquid-crystal electro-opticaldevice 1 inch in diagonal according to the invention was fabricated. Thedevice had 387×128 pixels. The viewfinder was fabricated fromhigh-mobility TFTs (thin-film transistors) in a low-temperature process.The arrangement of active elements on the substrate of a liquid-crystalelectro-optical device used in the present example is shown in FIG. 7.FIG. 6 is a circuit diagram of the present example. The manufacturingsteps are shown in FIGS. 8, (A)-(F), which are taken along lines A-A'and B-B'. The cross sections taken along the line A-A' show an n-channelTFT. The cross sections taken along the line B-B' show a p-channel TFT.

In FIG. 8(A), a glass substrate 400 was made of an inexpensive materialand withstood a thermal treatment below 700° C., e.g., at about 600° C.Silicon oxide was sputtered on the glass substrate 400 to a thickness of1000 to 3000 Å by a magnetron RF (high frequency) sputtering process toform a blocking layer 401. The ambient was 100% oxygen. The film wasformed at 150° C. The output of the magnetron was 400 to 800 W. Thepressure was 0.5 Pa. The used target was made of quartz or a singlecrystal or silicon. The deposition rate was 30 to 100 Å/min.

A film of silicon was formed on this blocking layer 401 by low-pressureCVD (LPCVD), sputtering, or plasma-assisted CVD. Where the film wasbeing formed by low-pressure CVD, disilane (Si₂ H₆) or trisilane (Si₃H₈) was supplied into the CVD equipment at a temperature (e.g., 450 to550° C.) lower than the crystallization temperature by 100 to 200° C.,e.g., at 530° C. The pressure inside the reaction furnace was 30 to 300Pa. The deposition rate was 50 to 250 Å/min. To make the p-channel andn-channel TFTs have substantially uniform threshold voltage Vth, boronin the form of diborane may be added to the film at a concentration of1×10¹⁵ to 1×10¹⁸ atoms/cm³.

Where the sputtering process was used, the back pressure prior to thesputtering was 1×10⁻⁵ Pa or less. A single crystal of silicon was usedas a target. The process was carried out within an ambient of argon towhich 20-80% hydrogen was added. For example, argon accounted for 20%,while hydrogen accounted for 80%. The film was formed at 150° C. The RFfrequency was 13.56 MHz. The sputtering output was 400 to 800 W. Thepressure was 0.5 Pa.

Where the silicon film was formed by plasma-assisted CVD, thetemperature was 300° C., for example. Monosilane (SiH₄) or disilane (Si₂H₆) was used. This material was introduced into the PCVD equipment. Thefilm was formed while applying RF electric power of 13.56 MHz.

Preferably, the oxygen content of the films formed by these methods are5×10²¹ atoms/cm³ or less. If this oxygen concentration is high, it isdifficult to crystallize the film. As a result, it is necessary toelevate the thermal annealing temperature or to lengthen the thermalannealing time. Conversely, if the oxygen concentration is too low, theleakage current in OFF state is increased due to backlight. Therefore,the appropriate concentration ranges from 4×10¹⁹ to 4×10²¹ atoms/cm³.The hydrogen concentration was 4×10²⁰ atoms/cm³, which was 1 atomic % ofthe silicon concentration of 4×10²² atoms/cm³.

After the amorphous silicon film was formed to a thickness of 500 to5000 Å, e.g., 1500 Å, by any of the above-described methods, thelaminate was thermally treated at a middle temperature of 450 to 700° C.for 12 to 70 hours within a nonoxidizing ambient. For example, thelaminate was placed within an ambient of hydrogen at 600° C. Since theamorphous silicon oxide film was formed at the surface of the substrateunder the silicon film, no specific nuclei existed during this thermaltreatment. Hence, the whole laminate was annealed uniformly. That is,during the formation of the film, it assumed an amorphous structure.Hydrogen was merely mixed into it.

The silicon film was shifted from the amorphous state to a more highlyordered state by the annealing. Portions of the silicon film assumed acrystalline state. Especially, those regions which assumed acomparatively ordered state during the formation of the silicon filmtended to crystallize. However, intervening silicon atoms between thesehighly ordered regions couple together these regions and, therefore, thesilicon atoms attract each other. Measurement by laser Ramanspectroscopy has shown that peaks shifted toward lower frequencies fromthe peak 522 cm⁻¹ of a single crystal of silicon existed. Calculationfrom the half-width values has revealed that the apparent particlediameters ranged from 50 to 500 Å. That is, they resembledmicrocrystallites. In practice, however, there existed numerouscrystalline regions, i.e., clusters were produced. These clusters wereanchored to each other by the silicon atoms. The resulting coating had asemi-amorphous structure.

As a result, it might be said that substantially no grain boundariesexisted in this coating. Since carriers can move easily from cluster tocluster through the anchored locations, the carrier mobility is higherthan polycrystalline silicon having clear grain boundaries. Morespecifically, the Hall mobility (μh) is 10 to 200 cm² /V·sec. Theelectron mobility (μe) is 15 to 300 cm² /V·sec.

If the coating is made polycrystalline by an anneal at a hightemperature between 900° C. and 1200° C. rather than by an anneal at amoderate temperature as described above, then the impurities in thecoating segregate because of solid-phase growth from nuclei. A largeamount of impurities such as oxygen, carbon, and nitrogen is containedin the grain boundaries. The mobility within one crystal is large.However, movement of the carriers is impeded by the barriers formed atthe grain boundaries. The result is that it is difficult to obtain amobility exceeding 10 cm² /V·sec. Therefore, it was necessary that theconcentration of oxygen, carbon, nitrogen, and other impurities be asmall or very small fraction of the impurity concentration in asemi-amorphous film. In this case, a mobility of 50 to 100 cm² /V·secwas obtained.

The silicon film formed in this way was photo-lithographically etched toform a semiconductor layer 403 for n-channel TFTs and a semiconductorlayer 404 for p-channel TFTs. The channel width of the layer 403 was 20μm. A silicon oxide film 403 which would become a gate-insulating filmwas formed to a thickness of 500 to 2000 Å, e.g., 1000 Å, under the sameconditions as the silicon oxide film forming the blocking layer. A smallamount of fluorine could be added during the formation of the siliconoxide film to fix sodium ions.

Then, an aluminum film was formed on the silicon oxide film. Thealuminum film was patterned, using a photomask. The result is shown inFIG. 8(B). A gate-insulating film 405 and a gate electrode portion 406for an n-channel TFT were formed. The length of these film 405 andelectrode portion 406, taken in the longitudinal direction of thechannel, was 10 μm. That is, the channel length was 10 μm. Similarly, agate-insulating film 407 and a gate electrode portion 408 for ap-channel TFT were formed. The length of these film 409 and electrodeportion 408, taken in the longitudinal direction of the channel was, 7μm. That is, the channel length was 7 μm. The thickness of the gateelectrode portions 406 and 408 was 0.8 μm. In FIGS. 8(C), boron (B) wasimplanted into the source 409 and the drain 410 for the p-channel TFT ata dose of 1 to 5×10¹⁵ ions/cm². Then, as shown in FIG. 8(D), aphotoresist 411 was formed, using a photomask. Phosphorus (P) wasimplanted into the source 412 and the drain 413 for the n-channel TFT ata dose of 1 to 5×10¹⁵ ions/cm².

Subsequently, the gate electrode portions were anodized. L-tartaric acidwas diluted with ethylene glycol to a concentration of 5%, and the pHwas adjusted to 7.0±0.2, using ammonia. The laminate was dipped in thesolution and connected with the positive terminal of a constant currentsource. An electrode of platinum was connected to the negative terminal.An increasing voltage was applied while the current was maintained at 20mA. The oxidation process was continued until the voltage reached 150 V.Then, the oxidation process was continued while the voltage was kept at150 V until the current was reduced below 0.1 mA. In this way, analuminum oxide layer 414 was formed on the surfaces of the gateelectrode portions 406 and 408, thus giving rise to gate electrodes 415and 416 for an n-channel TFT and a p-channel TFT, respectively. Thethickness of the aluminum oxide layer 414 was 0.3 μm.

Then, the laminate was again annealed at 600° C. for 10 to 50 hours. Thedopants in the source 412 and drain 413 of the n-channel TFT and in thesource 409 and drain 410 of the p-channel TFT were activated so thatthese two kinds of regions doped n⁺ -type and p³⁰ type, respectively.Channel formation regions 417 and 418 were formed as semi-amorphoussemiconductors under the gate-insulating films 405 and 407,respectively.

In the present method, the ion implantation of dopants and theanodization around the gate electrodes may be carried out in reverseorder.

In this way, the insulating layer made of a metal oxide was formedaround the gate electrodes. As a result, the substantial length of eachgate electrode was shorter than the channel length by twice thethickness of the insulating film, in this case 0.6 μm. The formation ofthe offset regions to which no electric field was applied could reducethe leakage current in reverse bias.

In the present example, two anneals were conducted as shown in FIGS. 8;(A) and (E). Depending on the required characteristics, the anneal shownin FIG. 8(A) can be omitted. Both anneals may be carried out in one stepillustrated in FIG. 8(E), thus shortening the manufacturing time. InFIG. 8(E), an interlayer insulator 419 was formed by sputtering siliconoxide. This formation of the silicon oxide film can use LPCVD,photo-assisted CVD, or atmosphere-pressure CVD. The interlayer insulatorwas formed to a thickness of 0.2 to 0.6 μm, e.g., 0.3 μm. Subsequently,openings 420 for electrodes were formed, using a photomask. As shown inFIG. 8(F), aluminum was sputtered onto the whole laminate. Leads 421,423, and contacts 422 were formed, using a photomask. Thereafter,planarizing organic resin 424, e.g., polyimide resin that transmitslight, was applied to the laminate. Again, holes for the electrodes wereformed, using the photomask.

In order to use the two TFTs as a complementary pair and to connect thispair to one pixel electrode of a liquid-crystal device, an indium tinoxide (ITO) film was formed by sputtering, said one pixel electrodebeing a transparent electrode. This film was etched, using a photomask,to form electrodes 425. The ITO film was formed at a temperature betweenroom temperature and 150° C. and annealed at 200-400° C. in an ambientof oxygen or atmosphere. In this way, an n-channel TFT 426, a p-channelTFT 427, and the electrodes 425 of a transparent conductive film wereformed on the same glass substrate 401. The obtained TFTs exhibited thefollowing electrical characteristics. The mobility of the p-channel TFTwas 20 cm² /V·sec, and the threshold voltage Vth was -5.9 V. Themobility of the n-channel TFT was 40 cm² /V·sec, and the thresholdvoltage Vth was 5.0 V.

One substrate of a liquid-crystal electro-optical device was fabricatedby the method described above. The arrangement of the electrodes andother components of this liquid-crystal electro-optical device is shownin FIG. 7. The n-channel TFT 426 and the p-channel TFT 427 were formedat the intersection of a first signal line 428 and a second signal line429. Complementary pairs of TFTs of such a construction were arranged inrows and columns. The n-channel TFT 426 was connected to the secondsignal line 429 via the lead 421 at the input terminal of the drain 413.The gate electrode portion 406 was connected with the first signal line428 which forms multilayered wiring. The output terminal of the source412 is connected to the pixel electrodes 425 via contacts 422.

On the other hand, with respect to the p-channel TFT 427, the inputterminal of the drain 410 was connected with the second signal line 429via the lead 423. The gate electrode portion 408 was connected with thesignal line 428. The output terminal of the source 409 is connected withthe pixel electrodes 425 via the contacts 422, in the same way as then-channel TFT. This structure is repeated horizontally and vertically tocomplete the present example.

As a second substrate, silicon oxide was sputtered on a soda-lime glassto a thickness of 2000 Å. Again, an ITO film was formed on thissubstrate by sputtering at a temperature between room temperature and150° C. The film was annealed at 200-400° C. in an ambient of oxygen oratmosphere. A color filter was formed on this substrate, thus completingthe second substrate.

A mixture containing 6 parts of acrylic resin that hardens onillumination of ultraviolet radiation and 4 parts of a nematic liquidcrystal was sandwiched between the first and second substrates. Theperiphery of the substrates was fixed with epoxy resin. Since the leadson the substrates were spaced only 46 μm from each other, they wereconnected by the COG method. In the present example, gold bumps formedon an IC chip were connected by means of epoxy silver-palladium resin.The spaces between the IC chip and the substrates were buried withepoxy-modified acrylic resin, whereby all of them were bonded togetherhermetically. Then, polarizing plates were stuck to the outside. As aresult, a transmission-type liquid-crystal electro-optical device wasobtained.

EXAMPLE 2

FIGS. 10, (A)-(D), show cross-sections of the present example. Asubstrate 501 was fabricated from Corning 7059 glass. Then, anunderlying silicon oxide film 502 was formed to a thickness of 100 nm bysputtering. Also, an amorphous silicon film 503 was formed to athickness of 50 nm by plasma-assisted CVD. To protect the amorphoussilicon film, a silicon oxide film 504 was formed to a thickness of 20nm also by sputtering. The laminate was annealed at 600° C. for 72 hourswithin an ambient of nitrogen to recrystallize the films. Therecrystallized films were patterned by a photolithographic method andreactive ion etching (RIE) to form semiconductor island regions as shownin FIG. 10(A). Then, the protective silicon oxide film 504 was removedby wet etching, using buffered hydrofluoric acid that was a solution ofa mixture of hydrogen fluoride and ammonium fluoride. An example of thissolution consisted of 1 part by weight of high-purity hydrofluoric acid(50% by weight) used for semiconductor fabrication and 10 parts byweight of a solution of ammonium fluoride (40% by weight) used forsemiconductor fabrication. This buffered hydrofluoric acid etchedsilicon oxide at a rate of 70 nm/min, etched silicon at a rate of 60nm/min, and etched aluminum at a rate of 15 nm/min.

A gate oxide film 505 having a thickness of 115 nm was formed bysputtering in an ambient of oxygen while using silicon oxide as atarget. Under this condition, phosphorus ions were implanted into thegate oxide film 505 by a plasma doping method to getter the movableions, such as sodium, existing inside the gate oxide film. Where theconcentration of sodium is so low that the operation of the device isnot impeded by the movable ions, it is not necessary to conduct the ionimplantation. In the present example, the plasma-accelerating voltagewas 10 keV. The dose was 2×10¹⁴ ions/cm². The laminate was annealed at600° C. for 24 hours. As a result, the damage to the oxide film and tothe silicon film by the bombardment of the plasma doping was recovered.

Then, an aluminum film was formed by sputtering and patterned with amixed acid, i.e., a solution of phosphoric acid to which 5% nitric acidwas added, to form gate electrodes and their interconnects 506. Theetching rate was 225 nm/min. when the etching temperature was 40° C. Inthis way, the contours of the TFTs were adjusted. At this time, thelength of the channel was 8 μm, and the width was 20 μm.

N-type doped regions 507, or source and drain, were formed in thesemiconductor region by ion implantation. In this step, phosphorus ionswere implanted as dopant ions. The energy of the ions was 80 keV, andthe dose was 5×10¹⁵ ions/cm ². As shown, the dopant ions were implantedthrough the oxide film. The advantage of the use of this implantation isthat during subsequent recrystallization utilizing laser annealing, thesmoothness of the surfaces of the doped regions is maintained. Wherethis implantation is not employed, numerous crystal nuclei form on thesurfaces of the doped regions during recrystallization, thus giving riseto unevenness on the surfaces. In this way, the structure shown in FIG.10(B) was derived. Of course, the crystallinity of doped portions isseverely deteriorated by this ion implantation. These portions aresubstantially in amorphous state or in polycrystalline state close tothe amorphous state.

An electrical current was passed through the interconnects 506. A film508 of aluminum oxide was formed on the top surfaces and on the sidesurfaces of the gate electrodes and their interconnects by anodization.For this anodization, ethylene glycol solution of 3% tartaric acid wasneutralized with 5% ammonia to control the pH of the solution of7.0±0.2. Platinum was immersed as a cathode in the solution. Then, theTFTs were immersed in the solution together with the substrate. Theinterconnects 506 were connected with the anode of the power supply. Thetemperature was kept at 25±2° C.

Under this condition, an electrical current of 0.5 mA/cm² was firstpassed. When the voltage reached 200 V, the device was energized whilemaintaining the voltage constant. When the current reached 0.005 mA/cm²,the current was cut off, thus bringing the anodization to an end. Thethickness of the anodized film (anodic oxidation coating of the gateelectrode) obtained in this way was about 250 nm. This is illustrated inFIG. 10(C).

Subsequently, the laminate was laser annealed, using a KrF excimerlaser. For instance, 10 shots of laser pulses having a power density of350 mJ/cm² were illuminated. We have confirmed that the crystallinity ofthe amorphous silicon can be recovered to such an extent that theamorphous silicon can withstand the operation of the TFTs by at leastone shot of laser radiation. To sufficiently reduce the possibility ofoccurrence of defects due to fluctuations of the power of the laser, asufficient number of shots of laser pulses are desired. However, toomany shots of laser radiation will deteriorate the productivity. We havefound that 10 shots or so which are used in the present example are mostdesirable.

The laser anneal was conducted within the atmosphere to increase theproductivity. No problems took place, since the silicon oxide film hadbeen already formed on the doped regions. Where the laser anneal wascarried out while exposing the doped regions, oxygen entered the dopedregions from the atmosphere simultaneously with the crystallization,thus deteriorating the crystallinity. Hence, TFTs having satisfactorycharacteristics could not be obtained. Therefore, laminates in whichdoped regions were exposed were required to be laser annealed in vacuum.

In the present example, as shown in FIG. 10(D), a laser radiation wasmade to obliquely enter the laminate. As an example, the laser radiationwas at an angle of 10° to the normal to the substrate. The angle isdetermined according to the design specifications of the manufactureddevices. Of the doped regions, the regions crystallized by the laser canbe made asymmetrical. That is, regions 509 and 510 are doped regionswhich are sufficiently crystallized. A region 511 is not a doped regionbut crytallized by the laser radiation. A region 512 is a doped regionbut is not crystallized. For example, the doped region on the right sideof FIG. 10(D) may be used as the drain in which hot electrons tend tooccur.

In this way, the shapes of the devices were adjusted. Then, siliconoxide was sputtered to form an interlayer insulator in the conventionalmanner. Holes for electrodes were formed by a well-knownphotolithographical technique to expose the surface of the semiconductorregion or the surfaces of the gate electrodes and their interconnects.Finally, a metal coating was selectively formed. In this way, a devicewas completed.

EXAMPLE 3

In the TFTs fabricated in accordance with the present invention, thewidth of the amorphous semiconductor region and the width of each offsetregion affect not only the OFF current but also the voltage-withstandingcapability between the source and drain and the operating speed.Therefore, TFTs meeting the objective can be built by optimizing aparameter such as the thickness of the anodized film or the energy ofimplanted ions. However, it is generally impossible to adjust suchparameters of individual TFTs formed on one substrate separately. Forexample, an actual circuit is required that TFTs operating at a lowspeed and withstanding high voltages and TFTs operating at a high speedand withstanding low voltages be formed on the same substrate. Inaccordance with the fundamental principle of the present invention, withincreasing the width of each offset region or of the doped amorphoussemiconductor region, the OFF current decreases and the resistance tovoltage improves but the operating speed drops.

This example solves this problem and is next described by referring tothe plan views of FIGS. 11, (A)-(C), and to the cross sections of FIGS.12, (A)-(D). This example pertains to manufacture of a circuit used inan image display method using both a p-channel TFT and an n-channel TFTto activate one pixel, as described in Japanese Patent application Ser.No. 296331/1991. This n-channel TFT is required to operate at a highspeed but suffices to withstand only low voltages. On the other hand,the p-channel TFT is not required to operate at a very high speed butits OFF current must be low. In some cases, it is necessary that thep-channel TFT withstand high voltages. Accordingly, the requirement isthat the anodized film of the n-channel TFT be thin (20 to 100 nm) andthat the anodized film of the p-channel TFT be thick (250 to 400 nm).Steps for manufacturing the present example are described below.

A substrate 601 was fabricated from Corning 7059 glass, in the same wayas in Example 2. An n-type doped region 602, a p-type doped region 603,a gate-insulating film 604, gate electrodes 606 and 607, and itsinterconnects were formed. The gate electrodes 606 and 607 and itsinterconnects were connected with an interconnect 650 (FIGS 11(A) and12(A)).

An electrical current was passed through the gate electrodes 606 and 607and its interconnects. Films 613 and 614 of aluminum oxide were formedon the top and side surfaces of the gate electrodes 606 and 607 and itsinterconnects by anodization. The anodization was carried out similarlyto Example 2 except that the maximum voltage was 50 V. The thickness ofthe anodized film fabricated in this step was about 60 nm (FIG. 12(B)).

Referring to FIG. 11(B), gate electrodes and their interconnects 606were cut away from the interconnect 650 at 651 by laser etching. Underthis condition, anodization was again initiated. The conditions weresimilar to the previous conditions except that the maximum voltage wasincreased to 250 V. Since no current flowed through the interconnect606, no change was observed. However, an aluminum oxide film 615 havinga thickness of about 300 nm was formed around the gate interconnects607, because an electrical current flowed through the interconnects 607(FIG. 12(C)).

Then, the laminate was laser annealed under the same conditions as inExample 2. In this case, in the n-channel TFT (on the left side of FIGS.12. (A)-(D)), the width a₁ of the amorphous region and of the offsetregions was so narrow that it could be neglected. Where the surface ofthe aluminum interconnects was not coated with an anodized film, theinterconnects were severely damaged by laser illumination. Therefore, itwas necessary to form an anodized film though it was thin. On the otherhand, in the p-channel TFT (on the right side of FIG. 12), the thicknessof the anodized film was 300 nm. Also, amorphous regions 150 to 200 nmthick existed. The width a₂ of the offset regions was estimated to be100 to 150 nm (FIG. 12(D)).

In the same way as in Example 2, the aluminum interconnects were etchedat requisite locations by laser irradiation within the atmosphere. Thegate electrode of the p-channel TFT was separated from the interconnect607. Also, the interconnect 650 was cut off. An interlayer insulatingfilm was formed. Contact holes were formed. Interconnects 624 and 611were formed. In this way, a circuit was formed.

In the circuit fabricated in this way, the offset regions and theamorphous region of the n-channel TFT were narrow. The speed ofoperation was excellent though the OFF current was slightly large. Onthe other hand, it was difficult to operate the p-channel TFT at a highspeed. However, the OFF current was small. The ability to hold theelectric charge stored in the pixel capacitor was excellent.

There exist other situations in which TFTs having different functionsmust be packed on one substrate. For example, in a liquid-crystaldisplay driver, high-speed TFTs are required for the logic circuitsincluding shift registers, whereas TFTs withstanding high voltages arerequired for the output circuit. The method of this example is effectivein fabricating TFTs which must satisfy such conflicting requirements.

EXAMPLE 4

An active-matrix circuit consisting of n-channel TFTs as shown in FIG.13 was fabricated by the method used in Example 1. This active matrixcomprised gate lines 701 and data lines 702 which were arranged in rowsand columns. These lines were made of low-resistivity aluminum andcoated with an aluminum oxide film having a thickness of 200 to 400 nmbecause the circuit underwent an anodization step according to theinvention. The width of these lines was 2 μm. The thickness of theselines was 0.5 μm. Gate electrodes 703 of the TFTs for pixels wereconnected with the gate lines 701. The gate electrodes were also coatedwith aluminum oxide. A semiconductor layer 704 was formed under the gateelectrodes. In the same way as the n-channel TFTs of Example 1, thereexisted n-type polycrystalline regions doped with phosphorus. Withrespect to offset regions which constitute one feature of the invention,their width was set to about 200 to 400 nm. The sources of thissemiconductor layer were in contact with the data lines 702. The drainswere connected via aluminum electrodes 705 with pixel electrodes 706made of ITO.

FIG. 14 is a circuit diagram of an active-matrix device fabricated inthe present example. As described previously, in the matrix circuit ofthis structure, it is known that when the charging of a capacitor C_(LC)ends and the gate voltage ceases, the capacitor C_(LC) is capacitivelycoupled to the gate line via the parasitic capacitance C_(GD) of bothgate and drain. The voltage drops by ΔV from the charging voltage. Thisphenomenon is also observed in a circuit in which n-channel andp-channel TFTs are connected in parallel. This is described in detail inJapanese Patent application Ser. No. 208648/1991 filed by the presentapplicant.

As shown in FIG. 14, in a circuit consisting of only one TFT, i.e.,either an n-channel TFT or a p-channel TFT, the voltage drop is givenby.

    ΔV=C.sub.GD ·V.sub.G /(C.sub.LC +C.sub.GD)

where V_(G) is the difference between the ON voltage and OFF voltage ofthe gate voltage. For example, in a TFT fabricated without using aself-aligning process, the parasitic capacitance C_(GD) is quite largeand so the voltage drop ΔV is also large. To solve this problem, astorage capacitor C_(AD) was connected in parallel with the pixelcapacitor as shown in FIG. 14 to increase the apparent capacitance ofthe pixel capacitor. However, this method does not fundamentally solvethe problem. As described already, new problems such as a decrease inthe aperture ratio are induced.

Even for devices fabricated by a self-aligning process, if the size ofthe pixels is so small that the effect of the parasitic capacitance ofthe TFTs compared with the pixel capacitance cannot be neglected, thenthis voltage drop poses a serious problem. For example, in a panel 3inches in diagonal which is used for projection and matcheshigh-definition television, the pixel capacitance is as small as 13 fF.On the other hand, where TFTs are fabricated by a process using 2 μmrules, the aspect ratio of the interconnects is large. As a result, evenif no overlapping exists, parasitic capacitance is produced in threedimensions geometrically. The capacitance reaches several fF, which is10% or more of the pixel capacitance.

An active-matrix circuit using conventional TFTs is shown in FIG. 14(A).Obviously, the correct display to be provided is impeded by the voltagedrop ΔV. Specifically, in order to operate TFTs at a high speed, thegate voltage must be higher than the drain voltage. Usually, a voltageabout twice as high as the drain voltage is used as the gate voltage.Therefore, if the drain voltage is 5 V, the gate voltage is 10 V ormore. Where the gate voltage is made negative in OFF state to perfectthe operation of the TFTs, the gate voltage varies to a larger extent.In the case of FIG. 14, the drain voltage is alternating current of ±6V. The gate voltage is +12 V in ON state and -4 V in OFF state. From theequation above, we have the relation V_(G) =16 V. If the parasiticcapacitance is 2 fF, the voltage drop ΔV is 2 V, as shown in FIG. 14(A).This reaches indeed one third of the drain-charging voltage. Of course,the electric charge stored in the pixel is discharged by spontaneousdischarge and, therefore, it is more difficult in practice to provide anideal display. To avoid this problem, storage capacitors must beprovided at the expense of the aperture ratio.

On the other hand, in accordance with the present invention, theparasitic capacitance can be reduced greatly. More specifically, thecapacitance can be reduced below 0.1 fF. Therefore, the voltage drop ΔVcan be almost neglected, as shown in FIG. 14(B). Furthermore, inaccordance with the present invention, the OFF current is smaller thanthe OFF current of TFTs fabricated by the prior art method by about oneorder of magnitude. Consequently, the spontaneous discharge is muchmilder. Hence, an almost ideal display can be provided.

EXAMPLE 5

FIG. 15 shows an example of the present invention. A non-alkali glasssuch as Coning 7059 or quartz was utilized as a substrate. Othersubstrate material can be utilized, too. It is also desirable to coverthe surface of the substrate with a material with good heat conductivitylike aluminum nitride. In this example, anodic oxidation is performed ina latter process. During the oxidation, only the portion of anodicoxidation is heated. Because the usual glass substrate does not havehigh heat conductivity, it may result in peeling and other bad effectsas a result of heat reserve. If a material with good heat conductivitysuch as aluminum nitride, aluminum oxide is utilized as a substrate,such things cannot happen.

A substrate silicon oxide layer 1102 was formed on a substrate 1101 by200-2000 Å. Island crystal silicon films 1103 and 1104 were formedthereon. The thickness of this silicon film was 300-1500 Å. Here, 1103was for high-speed operation TFTs, and 1104 was for low leak currentTFTs. The former was appropriate for the purpose of an operationalcircuit, an image information process circuit, a shift register, and thelike. The latter was appropriate for the purpose of an active matrixelement of a liquid crystal display device.

The method of manufacturing the island crystal silicon is only brieflyshown here. An amorphous silicon film was formed by a deposition methodsuch as plasma CVD method or low-pressure CVD method. There are twomethods for crystallizing. One method is a method of annealing at500-650° C. for 2-48 hours. In this case, above mentioned amorphoussilicon film must have thickness of 750 Å or more. A silicon oxide filmof 100-1000 Å thickness was deposited on it as a cap film, and wasannealed in an electric furnace. After this annealing, this waspatterned into the island silicon film.

The other method is a method of crystallizing a silicon film momentarilyby radiating a strong light energy like laser or flash lamp. In thiscase, it is appropriate the thickness of the amorphous silicon film is750 Å or less. To prevent stress caused by different thermal expansions,the amorphous silicon film is crystallized by radiation of strong lightenergy like laser of flash lamp, without forming a cap film and thelike.

In this way, after obtaining an island silicon film, a silicon oxidefilm 1105 was formed as a gate insulating film by 500-1500 Å on thewhole surface. As a formation method of this silicon oxide film, asputter method or a plasma CVD method was appropriate. If heatresistance of the substrate allowed, the silicon oxide film obtained byheat oxide method of the island silicon showed a very goodcharacteristic. In the case of forming a silicon oxide film by plasmaCVD method, a film with good step coverage was obtained by utilizingtetra.ethoxy.silane(TEOS). To improve the characteristic further, it isdesirable to perform annealing in an inactive gas such as nitrogen orargon, at 450-550° C.

After that, a first wiring, that is, a wiring to be a gate wiring ofTFTs was formed by a sputter method. Aluminum was utilized as a materialof the wiring. Not only pure aluminum, but also aluminum including0.5-2% silicon can be utilized. This aluminum was patterned and gateelectrodes 1106 and 1107 were formed. In addition, all of the aluminumwirings formed here were connected. (FIG. 15(A))

Next, the substrate was dipped in an ethylene glycol solution of 1-5%tartaric acid(pH≈7.0), an aluminum wiring was connected to an anode, aplatinum electrode was used as a cathode, and current was applied. Thusan anodic oxide was formed on the aluminum wiring. Here, oxidation wasperformed at first with applying constant current. When voltage wasincreased to a decided level, the voltage was kept at the decided leveluntil current becomes 100 μA/cm² or less. In a condition with constantelectric current of the first stage, the surface condition of the oxidefilm was greatly affected by the speed of voltage increase. Generallyspeaking, the faster the rising speed, the rougher the surface became.The amount of silicon included also affected the surface condition. Inthe opinion of this inventor, 2 V/minute or less for pure aluminum, 1.5V/minute or less for aluminum including 2% silicon was appropriate. Inthis example, voltage was increased to be 100 V at a rate of 1.2V/minute. As a result, an anodic oxide (aluminum oxide) with 1000 Åthickness 1108 and 1109 was obtained. (FIG. 15(B))

Next, a photoneece (UR3800 manufactured by Toray Co., Ltd.) was coatedon the whole surface of the substrate by spin coater. The cycle ofcirculation was 2500 rpm. After it was dried in a nitrogen atmosphere at80° C. for an hour, this photoneece was patterned by a usual exposingmethod. In this case, the portion on high-speed TFTs (on the left sideof the figure) only was left. Finally, the photo varnish 1110 left inthis way was made into polyimide by baking it at 300° C. for 0.5-2hours. After that, by above mentioned anodic oxidation method, anodicoxidation was performed again. In this case, anodic oxidation does notproceed on the portion covered with the polyimide 1110. Therefore, as isshown in FIG. 15(C), anodic oxidation was effected in the wiring 1107only. Here, applied voltage was increased to be 220 V. Therefore, athick anodic oxide 1111 with 2500 Å thickness was formed around thewiring 1107. (FIG. 15(C))

After that, an impurity (phosphorous or boron) was introduced into asilicon film in self-align way by ion injection method or plasma dopingmethod, with the gate electrode and an oxide around it as a mask.Impurity regions 1112 and 1113 were formed. Here, the size of offsetbetween the impurity region and the gate electrode was decided by thethickness of anodic oxide as is shown in FIG. 15(D). That is, because ananodic oxide 1108 was thin in the TFTs in the left part of the figure(for high-speed operation), offset a was small. On the other hand,because an anodic oxide 1111 was thick in the TFTs in the right part ofthe figure (for low leak current), offset b was big. That is, there is arelationship of a<b. (FIG. 15(D))

Then, to improve conductivity of the impurity region, a strong lightenergy such as laser or flash lamp was radiated and crystal character ofthe impurity region was made better. Furthermore, by a well knownmultilayer interconnection technology, a wiring of the second layer wasformed. That is, as an interlayer insulator 1114, a silicon oxide filmof 2000-6000 Å thickness was deposited by a plasma CVD method. A contacthole was formed there, and a metal film such as a multilayer film oftitanium nitride (200-1000 Å thickness) and aluminum (500-5000 Åthickness) was deposited by a sputter method and the like. This waspatterned, and electrodes•wirings 1115, 1116, 1117, and 1118 wereformed. (FIG. 15(E))

In the circuit formed in this way, a shift register was formed byutilizing high-speed TFTs, and its operation of 6.2 MHz at a drainvoltage of 10 V, and 11.5 MHz at 20 V was confirmed. On the other hand,mobility of low leak current TFTs was 50-110 cm² /Vs for NMOS, but leakcurrent was 10 fA or less in the condition of gate voltage of 0 V anddrain voltage of 1 V, for NMOS.

EXAMPLE 6

FIG. 16 shows an example of the present invention. A non-alkali glasssuch as Coning 7059 or quartz was utilized as a substrate. Othersubstrate material can be utilized, too. It is also desirable to coverthe surface of the substrate with a material with good heat conductivitylike aluminum nitride, as was explained in Example 5. A substratesilicon oxide film 1202 was formed on a substrate 1201 by 200-2000 Å. Anisland crystal silicon film was 300-1500 Å. After obtaining the islandsilicon film, a silicon oxide film 1203 was formed as a gate insulatingfilm on the whole surface by 500-1500 Å.

After that, a first wiring, that is, a wiring to be a gate wiring ofTFTs was formed by a sputter method. Aluminum was utilized as a materialof the wiring. Not only pure aluminum, but also aluminum including0.5-2% silicon can be utilized. This aluminum was patterned and a gateelectrode 1205 and a wiring 1206 in the same layer as the gate electrode1205 were formed. (FIG. 16(A))

Next, the substrate was dipped in an ethylene glycol solution of 1-5%tartaric acid (pH=7.0), an aluminum wiring was connected to an anode, aplatinum electrode was used as a cathode, and current was applied. Thusan anodic oxide was formed on the aluminum wiring. Here, an anodic oxide(aluminum oxide) with 1000 Å thickness 1207 and 1208 was obtained. (FIG.16(B))

Next, a photoneece (UR3800 manufactured by Toray Co., Ltd.) was coatedon the whole surface of the substrate by spin coater. After it wasdried, this photoneece was patterned. In this case, the portion on TFTs(on the left side of the figure) only was left. Finally, the photoneece1209 left in this way was made into polyimide by baking it at 300° C.for 0.5-2 hours. After that, by above mentioned anodic oxidation method,anodic oxidation was performed again. In this case, anodic oxidationdoes not proceed on the portion covered with the polyimide 1209.Therefore, as is shown in FIG. 16(C), anodic oxidation was effected inthe wiring 1206 only. Here, applied voltage was increased to be 220 V.Therefore, a thick anodic oxide 1210 with 2500 Å thickness was formedaround the wiring 1206. (FIG. 16(C))

After that, an impurity (phosphorous or boron) was introduced into thesilicon film in self-align way by ion injection method or plasma dopingmethod, with the gate electrode and an oxide around it as a mask. Animpurity region 1211 was formed. Here, the size of offset between theimpurity region and the gate electrode is decided by the thickness ofanodic oxide as is shown in FIG. 16(D). In this case, offset ofapproximately 1000 Å was formed. (FIG. 16(D))

Then, to improve conductivity of the impurity region, a strong lightenergy such as laser or flash lamp was radiated and crystal character ofthe impurity region was made better. Furthermore, by a well knownmultilayer interconnection technology, a wiring of the second layer wasformed. That is, as an interlayer insulator 1212, a silicon oxide filmof 2000-6000 Å thickness was deposited by a plasma CVD method. A contacthole was formed there, and a metal film such as a multilayer film oftitanium nitride (200-1000 Å thickness) and aluminum (500-5000 Åthickness) was deposited by a sputter method and the like. This waspatterned, and electrode-wirings 1213 and 1214 were formed. (FIG. 16(E))

As is shown in the figure, the wiring 1214 is crossed with the wiring1206. At this crossing portion, not only the interlayer insulator 1212but also an anodic oxide 1210 with high insularity existed. The anodicoxide formed around the wiring 1206 is thicker than the anodic oxideformed around the gate electrode 1205. It is expected that the anodicoxide 1210 shows enough insularity at an applied voltage of 200 V in themanufacturing process. On the other hand, because the thickness of ananodic oxide 1207 in the peripheral portion of the gate electrode ofTFTs was approximately 1000 Å, this was not a problem for high-speedoperation of the TFTs. Actually the mobility of the TFTs was 80-150 cm²/Vs for NMOS.

EXAMPLE 7

FIG. 17 shows an example of the present invention. A non-alkali glasssubstrate such as Coning 7059 or quartz was utilized as a substrate.Other substrate material can be utilized, too. It is also desirable tocover the surface of the substrate with a material with good heatconductivity like aluminum nitride, as was explained in Example 5. Asubstrate silicon oxide film 1302 was formed on a substrate 1301 by200-2000 Å. An island crystal silicon film 1303 was formed thereon. Thethickness of this silicon film was 300-1500 Å. After obtaining theisland silicon film, a silicon oxide film 1304 was formed on the wholesurface by 500-1500 Å.

After that, a first wiring, that is, a wiring to be a gate wiring ofTFTs was formed by a sputter method. Tantalum was utilized as a materialof the wiring. Tantalum nitride can be also utilized in place of metaltantalum. A sputter method was utilized as a deposition method. Thistantalum was patterned and a gate electrode 1305 and a wiring 1306 inthe same layer as the gate electrode 1305 were formed. (FIG. 17(A))

Next, the substrate was dipped in an ethylene glycol solution of 1-5%citric acid (pH=7.0), a tantalum wiring was connected to an anode, aplatinum electrode was used as a cathode, and current was applied. Thusan anodic oxide was formed on the tantalum wiring. Here, an anodic oxide(tantalum oxide) with 2000 Å thickness 1307 and 1308 was obtained. (FIG.17(B))

After that, an impurity (phosphorous or boron) was introduced into thesilicon film in self-align way by ion injection method or plasma dopingmethod, with the gate electrode and an oxide around it as a mask. Animpurity region 1309 was formed. Here, the size of offset between theimpurity region and the gate electrode is decided by the thickness ofanodic oxide as is shown in FIG. 17(C). In this case, offset ofapproximately 2000 Å was formed. (FIG. 17(C))

Next, a photoneece was coated on the whole surface and patterned andmade into polyimide. The photoneece only on the TFT (on the left side ofthe figure) was removed. With this photoneece 1310 left in this way as amask, tantalum oxide was etched in a plasma atmosphere of carbontetrafluoride and oxygen. Here, because the atmosphere gas includedoxygen, the photo varnish was also etched, but if this was made in 1-5μm thickness, it could bear until all anodic oxide 1307 was etched.Buffer hydrofluoric acid could be utilized for etching. In this case,though the photoneece is not etched, the gate oxide film, the substrateoxide film, and the substrate were etched. In this way, the anodic oxide1307 of the gate electrode was etched by 1000 Å or more, preferably, allof it. (FIG. 17(D))

Then, to improve conductivity of the impurity region, a strong lightenergy such as laser or flash lamp was radiated and crystal character ofthe impurity region was made better. In Examples 5 and 6, because ananodic oxide exists, light energy was difficult to be radiated to theinterface between an impurity region and an intrinsic semiconductorregion (channel formation region). This sometimes caused a problem toreliability. However, in the condition removed with an anodic oxide likein this example, light energy was fully radiated to the interface, too,and enough reliability was obtained.

Furthermore, by a well known multilayer interconnection technology, awiring of the second layer was formed. That is, as an interlayerinsulator 1311, a silicon oxide film of 2000-6000 Å thickness wasdeposited by a plasma CVD method. A contact hole was formed there, and ametal film such as a multilayer film of titanium nitride (200-1000 Åthickness) and aluminum (500-5000 Å thickness) was deposited by asputter method and the like. This was patterned, and electrode-wirings1312 and 1313 were formed. (FIG. 17(E))

Like in Example 6, the wiring 1313 was crossed with the wiring 1306. Atthis crossed portion, not only the interlayer insulator 1311 but also ananodic oxide 1308 with high insularity existed. The portion showedenough insularity as a result.

EXAMPLE 8

FIG. 18(A) shows an example of the present invention. This example wasperformed by utilizing technologies shown in Examples 5 to 7, and is anexample of a CMOS circuit utilized for a driving circuit of a liquidcrystal display and an image sensor. TFTs 1401 on the left of the figureis a PMOS, and TFTs 1402 on the right is an NMOS. Wirings of a firstlayer were 1403, 1404, 1405, and 1406. 1403 and 1404 were gateelectrodes. The thickness of the anodic oxide of them is thin (˜1000 Å),so as to be appropriate for high-speed TFTs. The anodic oxide of thewiring 1406 is thin (˜1000 Å) in the same way as the gate electrodes tocontact the 1407 being a wiring of a second layer. A contact hole isalso formed. Either one of the methods shown in FIG. 19 to FIG. 21 canbe adopted, but the method in FIG. 19 or FIG. 20 was easy to beperformed. The anodic oxide of the wiring 1405 was thick (˜2500 Å),because it was crossed with the wiring 1407 of the second layer, andenough insularity could be obtained.

EXAMPLE 9

FIG. 18(B) shows an example of the present invention. This example wasperformed by utilizing technologies shown in Examples 5 to 7, and is anexample of a peripheral circuit of a signal output utilized for adriving circuit of a liquid crystal display and an image sensor. TFTs1411 in the left of the figure are TFTs to control strong electriccurrent, and is typically a big one with a channel width of 500 μm-1 mm.TFTs 1412 in the right of the figure are TFTs for a logic circuit, andis typically a relatively small one with a channel width of 5-50 μm.

Wirings of a first layer were 1413, 1414, and 1415. 1413 and 1414 weregate electrodes. The thickness of the anodic oxide of 1414 is thin(˜1000 Å), so as to be appropriate for high-speed TFTs. The anodic oxideof a gate electrode 1413 was thick (˜3000 Å) because the TFTs 1411 wereTFTs for high voltage and strong electric current. The anodic oxide ofthe wiring 1415 was thin (˜1000 Å) in the same way as that of the gateelectrode to contact the 1416 being a wiring of a second layer. Acontact hole is also formed therein. Either one of the methods shown inFIG. 19 to FIG. 21 can be adopted, but the method in FIG. 19 or FIG. 20was easy to be performed. The wiring 1415 was continued to the gatewiring 1413.

EXAMPLE 10

FIG. 18(C) shows an example fo the present invention. This example wasperformed by utilizing technologies shown in Examples 5 to 7, and is anexample of a circuit around TFTs for controlling pixels of a liquidcrystal display. TFTs 1421 in the figure are TFTs for low leak current.Wirings of a first layer were 1422, 1423, and 1424. 1423 was a gateelectrode. The thickness of the anodic oxide of the gate electrodes 1423was thick (˜2000 Å), because low leak current was demanded for the TFTs1421. The anodic oxide of the wiring 1422 was also thick (˜2000 Å) toimprove insularity, because it was crossed with a wiring 1425 of asecond layer. The wiring 1424 constitutes a capacitor with a transparentconductive film extended from the drain of the TFTs. To improveelectrostatic capacitance, an interlayer insulator was not providedbetween them, and a dielectric was only an anodic oxide (aluminumoxide). What is more, the thickness of it was as thin as 1000 Å.

EXAMPLE 11

FIG. 22 shows this example. This example relates to a technology ofcontacting a wiring to be anodic oxidized with an upper wiring. Asubstrate silicon oxide film 802 was deposited on a substrate 801 likequartz, Corning 7059. A crystal island silicon film 803 and a siliconoxide film 804 as a gate insulating film were deposited, and gateelectrode•wiring 805, other wirings 806 and 807 were formed of aluminum.Because the wiring 807 must form a contact with an upper wiring, a maskmaterial 808 was formed by photoneece. (FIG. 22(A))

Current was run through the wirings 805 to 807 in an electrolytesolution, and a thin (1000 Å thickness) anodic oxide (aluminum oxide)film 809 was formed on portions not being covered with the maskmaterial. (FIG. 22(B))

After that, a gate electrode 805 of TFTs and the mask 808 of photoneeceformed before were covered, and masks 810 and 811 were newly formed ofphotoneece. (FIG. 22(C))

Anodic oxidation was performed again, and a thick (2500 Å) anodic oxide812 was formed on a portion not covered with the mask material. Aroundthe place of a contact hole in the wiring 807, the thickness of theanodic oxide decreases in steps in the direction of the contact hole.(FIG. 22(D))

After that, an impurity region 813 was formed, and an interlayerinsulator 814 was deposited. It was preferable the thickness of theinterlayer insulator was 5000 Å or more to improve insularity, butbecause a thick anodic oxide was formed in the portion where wiringswere crossed, thin thickness of 1000 -3000 Å of the interlayer insulatorwas not a problem. This interlayer insulator was patterned, and acontact hole was formed to the source, drain of TFTs, and the wiring807. A metal film was deposited further, and by patterning this, metalwirings 815, 816, and 817 were formed. Here, the wiring 817 contactedthe wiring 807 in the lower part. The upper wiring 817 was not easilycut, because different levels were gradually formed around the contacthole, and because the thickness of the interlayer insulator was thinnerthan that of usual cases. On the other hand, the wiring 816 was crossedwith the wiring 806. Because a thick anodic oxide 812 was formed in theportion where wirings were crossed, this and the interlayer insulatorgave enough insularity.

EXAMPLE 12

FIG. 23 shows this example. This example relates to a technology ofcontacting a wiring to be anodic oxidized with an upper wiring. Asubstrate silicon oxide film 902 was deposited on a substrate 901 likequartz, Corning 7059. A crystal island silicon film 903 and a siliconoxide film 904 as a gate insulating film were deposited, and a gateelectrode•wiring 905, other wirings 906 and 907 were formed of aluminum.Current was run through the wirings in an electrolyte solution, and athin (1000 Å thickness) anodic oxide (aluminum oxide) film 908 wasformed on the surface. (FIG. 23(A))

After that, a gate electrode 905 of TFTs and the portion of the wiring907 to which a contact hole is to be provided were covered, and masks909 and 910 were formed of photoneece. (FIG. 23(B))

Anodic oxidation was performed again, and a thick (2500 Å) anodic oxide911 was formed on a portion not covered with the mask material. (FIG.23(C))

The masks 909 and 910 were removed, an impurity region 912 was formed,and a contact hole of a thin anodic oxide film 908 was formed on thewiring 907. (FIG. 23(D))

An interlayer insulator 914 was deposited and patterned. A contact holewas formed on the source, drain of TFTs, and the wiring 907. A metalfilm was deposited further, and by patterning this, metal wirings 915,916, and 917 were formed. Here, the wiring 917 contacted the wiring 907in the lower part. The upper wiring 917 was not easily cut, becausedifferent levels were gradually formed around the contact hole. On theother hand, the wiring 916 was crossed with the wiring 906 Because athick anodic oxide 911 was formed in the portion where wirings werecrossed, this and the interlayer insulator gave enough insularity.

The effect of the present invention is, first of all, MIS transistorswith different characters can be formed on the same substrate in aprocess. As is clear from Example 5, to make two kinds of TFTs, just thefollowing two processes should be added:

(i) Coating of photoneece and patterning thereof

(ii) Second anodic oxidation

Photolithography process which decides yield is only (i), so thatdecrease of yield was little.

The second effect of the present invention is, as is shown in Example 6,a short circuit at the portion where wirings are crossed is decreasedvery much. Further, characteristic of an MIS transistor is kept. (Forexample, high-speed operation.) This is performed just by adding above(i) and (ii) processes, too, and contributed to improvement of yield.

The third effect of the present invention is shown in FIG. 19 to FIG. 21and a sentence corresponding to them. The thickness of the anodic oxideis changed in steps near the contact of the wiring in the first layerand the wiring in the second layer. Thus different levels made by thecontact hole are leveled, and cutting of the wiring of the second layerand the like are prevented.

Further, in accordance with the present invention, an insulating,anodized layer is formed at the surface of a gate electrode. As aresult, the channel length is larger than the length of the gateelectrode taken in the longitudinal direction of the channel. Hence,offset regions which receive no or very weak electric field from thegate electrode are formed on opposite sides of the channel region.Similarly, a doped amorphous semiconductor region having the sameadvantages can be formed. This reduces the leakage current in reversebias. In consequence, capacitance which would have been heretoforeneeded to hold electric charge is dispensed with. The aperture ratiowhich has been approximately 20% in the prior art technique can beimproved above 35%. Thus, display can be provided at higher quality.

In accordance with the present invention, the offset regions and thedoped amorphous semidconductor region are determined by the thickness ofthe anodized film of the gate electrode. Therefore, the width of theseregions can be controlled accurately to between 10 to 100 nm. We did notobserve a great reduction in the production yield when thismanufacturing step was added. Also, any factor which might be regardedas a cause of a decrease in the production yield did not existed.

While silicon semiconductor devices have been chiefly described thusfar, it is obvious that the invention can be applied to semiconductordevices using germanium, silicon carbide, gallium arsenide, or othermaterial.

What is claimed is:
 1. An active matrix display device comprising:asubstrate having an insulating surface; an active matrix circuit oversaid substrate, said active matrix circuit comprising:at least one thinfilm transistor having source and drain regions and a channel regiontherebetween in a semiconductor film, and a gate electrode adjacent tosaid channel region with a gate insulating film interposed therebetween;a pixel electrode formed over said substrate and electrically connectedto one of said source and drain regions; a capacitor formed between awiring and a portion of said pixel electrode with an oxide filminterposed therebetween, said oxide film comprising an oxidized surfaceof said wiring; and a CMOS circuit for driving said active matrixcircuit formed over said substrate, said CMOS circuit comprising atleast a pair of N-channel and P-channel thin film transistors.
 2. Anactive matrix display device according to claim 1 wherein at least oneof said wiring and said gate electrode comprises a material selectedfrom the group consisting of silicon, aluminum, tantalum, titanium,tungsten, molybdenum, an alloy thereof, tantalum nitride, titaniumnitride, tungsten nitride and molybdenum nitride.
 3. An active matrixcircuit according to claim 1 wherein said oxide film is formed by anodicoxidation.
 4. An active matrix display device comprising:a substratehaving an insulting surface; an active matrix circuit over saidsubstrate, said matrix circuit comprising:at least one thin filmtransistor having source and drain regions and a channel regiontherebetween in a semiconductor film, and a gate electrode adjacent tosaid channel region with a gate insulting film interposed therebetween;a pixel electrode formed over said substrate and electrically connectedto one of said source and drain regions; a capacitor formed between awiring and a portion of said pixel electrode with an oxide filminterposed therebetween, said oxide film comprising an oxidized surfaceof said wiring; and a peripheral circuit of a signal output utilized fora driving circuit of said active matrix display device, said peripheralcircuit comprising at least a first thin film transistor for controllingstrong electric current and a second thin film transistor for a logiccircuit.
 5. An active matrix display device according to claim 4 whereinat least one of said wiring and said gate electrode comprises a materialselected from the group consisting of silicon, aluminum, tantalum,titanium, tungsten, molybdenum, an alloy thereof, tantalum nitride,titanium nitride, tungsten nitride and molybdenum nitride.
 6. An activematrix circuit according to claim 4 wherein said oxide film is formed byanodic oxidation.
 7. An active matrix display device comprising:asubstrate having an insulating surface; an active matrix circuit oversaid substrate, said active matrix circuit comprising:at least one thinfilm transistor having source and drain regions and a channel regiontherebetween in a semiconductor film, and a gate electrode over saidchannel region with a gate insulating film interposed therebetween; apixel electrode formed over said substrate and electrically connected toone of said source and drain regions; a capacitor formed between awiring and a portion of said pixel electrode with an oxide filminterposed therebetween, said oxide film comprising an oxidized surfaceof said wiring; and a CMOS circuit for driving said active matrixcircuit formed over said substrate, said CMOS circuit comprising atleast a pair of N-channel and P-channel thin film transistors.
 8. Anactive matrix display device according to claim 7 wherein at least oneof said wiring and said gate electrode comprises a material selectedfrom the group consisting of silicon, aluminum, tantalum, titanium,tungsten, molybdenum, an alloy thereof, tantalum nitride, titaniumnitride, tungsten nitride and molybdenum nitride.
 9. An active matrixcircuit according to claim 7 wherein said oxide film is formed by anodicoxidation.
 10. An active matrix display device comprising:a substratehaving an insulating surface; an active matrix circuit over saidsubstrate, said active matrix circuit comprising:at least one thin filmtransistor having source and drain regions and a channel regiontherebetween in a semiconductor film, and a gate electrode over saidchannel region with a gate insulating film interposed therebetween; apixel electrode formed over said substrate and electrically connected toone of said source and drain regions; a capacitor formed between awiring and a portion of said pixel electrode with an oxide filminterposed therebetween, said oxide film comprising an oxidized surfaceof said wiring; and a peripheral circuit of a signal output utilized fora driving circuit of said active matrix display device, said peripheralcircuit comprising at least a first thin film transistor for controllingstrong electric current and a second thin film transistor for a logiccircuit.
 11. An active matrix display device according to claim 10wherein at least one of said wiring and said gate electrode comprises amaterial selected from the group consisting of silicon, aluminum,tantalum, titanium, tungsten, molybdenum, an alloy thereof, tantalumnitride, titanium nitride, tungsten nitride and molybdenum nitride. 12.An active matrix circuit according to claim 10 wherein said oxide filmis formed by anodic oxidation.
 13. An active matrix display devicecomprising:a substrate having an insulating surface; an active matrixcircuit over said substrate, said active matrix circuit comprising:atleast one thin film transistor having source and drain regions and achannel region therebetween in a semiconductor film comprisingcrystalline silicon, and a gate electrode adjacent to said channelregion with a gate insulating film interposed therebetween; atransparent conductive film formed over said substrate and electricallyconnected to one of said source and drain regions; a capacitor formedbetween a wiring and a portion of said transparent conductive film withan oxide film interposed therebetween, said oxide film comprising anoxidized surface of said wiring; and a CMOS circuit for driving saidactive matrix circuit formed over said substrate, said CMOS circuitcomprising at least a pair of N-channel and P-channel thin filmtransistors.
 14. An active matrix display device according to claim 13wherein at least one of said wiring and said gate electrode comprises amaterial selected from the group consisting of silicon, aluminum,tantalum, titanium, tungsten, molybdenum, an alloy thereof, tantalumnitride, titanium nitride, tungsten nitride and molybdenum nitride. 15.an active matrix circuit according to claim 13 wherein said oxide filmis formed by anodic oxidation.
 16. An active matrix display devicecomprising:a substrate having an insulating surface; an active matrixcircuit over said substrate, said active matrix circuit comprising:atleast one thin film transistor having source and drain regions and achannel region therebetween in a semiconductor film comprisingcrystalline silicon, and a gate electrode adjacent to said channelregion with a gate insulating film interposed therebetween; atransparent conductive film formed over said substrate and electricallyconnected to one of said source and drain regions; a capacitor formedbetween a wiring and a portion of said transparent conductive film withan oxide film interposed therebetween, said oxide film comprising anoxidized surface of said wiring; and a peripheral circuit of a signaloutput utilized for a driving circuit fo said active matrix displaydevice, said peripheral circuit comprising at least a first thin filmtransistor for controlling strong electric current and a second thinfilm transistor for a logic circuit.
 17. An active matrix display deviceaccording to claim 16 wherein at least one of said wiring and said gateelectrode comprises a material selected from the group consisting ofsilicon, aluminum, tantalum, titanium, tungsten, molybdenum, an alloythereof, tantalum nitride, titanium nitride, tungsten nitride andmolybdenum nitride.
 18. An active matrix circuit according to claim 16wherein said oxide film is formed by anodic oxidation.
 19. An activematrix display device comprising:a substrate having an insulatingsurface; an active matrix circuit over said substrate, said activematrix circuit comprising:at least one thin film transistor havingsource and drain regions and a channel region therebetween in asemiconductor film, and a gate electrode adjacent to said channel regionwith a gate insulating film interposed therebetween; a pixel electrodeformed over said substrate and electrically connected to one of saidsource and drain regions; a capacitor formed between a wiring and aportion of said pixel electrode with an anodic oxide film interposedtherebetween, said anodic oxide film comprising an oxidized surface ofsaid wiring; and a CMOS circuit for driving said active matrix circuitformed over said substrate, said CMOS circuit comprising at least a pairof N-channel and P-channel thin film transistors.
 20. An active matrixdisplay device according to claim 19 wherein at least one of said wiringand said gate electrode comprises a material selected from the groupconsisting of silicon, aluminum, tantalum, titanium, tungsten,molybdenum, an alloy thereo, tantalum nitride, titanium nitride,tungsten nitride and moylbdenum nitride.
 21. An active matrix displaydevice comprising:a substrate having an insulating surface; an activematrix circuit over said substrate, said active matrix circuitcomprising:at least one thin film transistor having source and drainregions and a channel region therebetween within a semiconductor film,and a gate electrode adjacent to said channel region with a gateinsulating film interposed therebetween. a pixel electrode formed oversaid substrate and electrically connected to one of said source anddrain regions; a capacitor formed between a wiring and a portion of saidpixel electrode with an anodic oxide film interposed therebetween, saidanodic oxide film comprising an oxidized surface of said wiring; and aperipheral circuit of a signal output utilized for a driving circuit ofsaid active matrix display device, said peripheral circuit comprising atleast a first thin film transistor for controlling strong electriccurrent and a second thin film transistor for a logic circuit.
 22. Anactive matrix display device according to claim 21 wherein at least oneof said wiring and said gate electrode comprises a material selectedfrom the group consisting of silicon, aluminum, tantalum, titanium,tungsten, moylbdenum, an alloy thereof, tantalum nitride, titaniumnitride, tungsten nitride and moylbdenum nitride.
 23. An active matrixdisplay device comprising:a substrate having an insulating surface; anactive matrix circuit over said substrate, said active matrix circuitcomprising;at least one thin film transistor having source and drainregions and a channel region therebetween in a semiconductor film, and agate electrode adjacent to said channel region with a gate insulatingfilm interposed therebetween; a pixel electrode formed over saidsubstrate and electrically connected to one of said source and drainregions; a capacitor formed between a wiring and a portion of said pixelelectrode with an oxide film interposed therebetween, said oxide filmcomprising an oxidized surface of said wiring; wherein said oxide filmhas a thickness less than 1000 Å; and a CMOS circuit for driving saidactive matrix circuit formed over said substrate, said CMOS circuitcomprising at least a pair of N-channel and P-channel thin filmtransistors.
 24. An active matrix display device according to claim 23wherein at least one of said wiring and said gate electrode comprises amaterial selected from the group consisting of silicon, aluminum,tantalum, titanium, tungsten, moylbdenum, an alloy thereof, tantalumnitride, titanium nitride, tungsten nitride and molybdenum nitride. 25.An active matrix circuit according to claim 23 wherein said oxide filmis formed by anodic oxidation.
 26. An active matrix display devicecomprising:a substrate having an insulating surface; an active matrixcircuit over said substrate, said active matrix circuit comprising:atleast one thin film transistor having source and drain regions and achannel region therebetween in a semiconductor film, and a gateelectrode adjacent to said channel region with a gate insulating filminterposed therebetween; a pixel electrode formed over said substrateand electrically connected to one of said source and drain regions; acapacitor formed between a wiring and a portion fo said pixel electrodewith an oxide film interposed therebetween, said oxide film comprisingan oxidized surface of said wiring; wherein said oxide film has athickness less than 1000 Å; and a peripheral circuit of a signal outpututilized for a driving circuit of said active matrix display device,said peripheral circuit comprising at least a first thin film transistorfor controlling strong electric current and a second thin filmtransistor for a logic circuit.
 27. An active matrix display deviceaccording to claim 26 wherein at least one of said wiring and said gateelectrode comprises a material selected from the group consisting ofsilicon, aluminum, tantalum, titanium, tungsten, molybdenum, an alloythereof, tantalum nitride, titanium nitride, tungsten nitride andmolybdenum nitride.
 28. An active matrix circuit according to claim 26wherein said oxide film is formed by anodic oxidation.
 29. An activematrix display device according to claim 1 wherein said oxide film has athickness less than 1000 Å.
 30. An active matrix display deviceaccording to claim 4 wherein said oxide film has a thickness less than1000 Å.
 31. An active matrix display device according to claim 7 whereinsaid oxide film has a thickness less than 1000 Å.
 32. An active matrixdisplay device according to claim 10 wherein said oxide film has athickness less than 1000 Å.
 33. An active matrix display deviceaccording to claim 13 wherein said oxide film has a thickness less than1000 Å.
 34. An active matrix display device according to claim 16wherein said oxide film has a thickness less than 1000 Å.
 35. An activematrix display device according to claim 19 wherein said anodic oxidefilm has a thickness less than 1000 Å.
 36. An active matrix displaydevice according to claim 21 wherein said anodic oxide film has athickness less than 1000 Å.
 37. An active matrix display deviceaccording to claim 1 wherein said pixel electrode comprises a conductivetransparent oxide film.
 38. An active matrix display device according toclaim 4 wherein said pixel electrode comprises a conductive transparentoxide film.
 39. An active matrix display device according to claim 7wherein said pixel electrode comprises a conductive transparent oxidefilm.
 40. An active matrix display device according to claim 10 whereinsaid pixel electrode comprises a conductive transparent oxide film. 41.An active matrix display device according to claim 19 wherein said pixelelectrode comprises a conductive transparent oxide film.
 42. An activematrix display according to claim 21 wherein said pixel electrodecomprises a conductive transparent oxide film.
 43. An active matrixdisplay device according to claim 23 wherein said pixel electrodecomprises a conductive transparent oxide film.
 44. An active matrixdisplay device according to claim 26 wherein said pixel electrodecomprises a conductive transparent oxide film.